'''ARMA process and estimation with scipy.signal.lfilter

2009-09-06: copied from try_signal.py
    reparameterized same as signal.lfilter (positive coefficients)


Notes
-----
* pretty fast
* checked with Monte Carlo and cross comparison with gwstatsmodels yule_walker
  for AR numbers are close but not identical to yule_walker
  not compared to other statistics packages, no degrees of freedom correction
* ARMA(2,2) estimation (in Monte Carlo) requires longer time series to estimate parameters
  without large variance. There might be different ARMA parameters
  with similar impulse response function that cannot be well
  distinguished with small samples (e.g. 100 observations)
* good for one time calculations for entire time series, not for recursive
  prediction
* class structure not very clean yet
* many one-liners with scipy.signal, but takes time to figure out usage
* missing result statistics, e.g. t-values, but standard errors in examples
* no criteria for choice of number of lags
* no constant term in ARMA process
* no integration, differencing for ARIMA
* written without textbook, works but not sure about everything
  briefly checked and it looks to be standard least squares, see below

* theoretical autocorrelation function of general ARMA
  Done, relatively easy to guess solution, time consuming to get
  theoretical test cases,
  example file contains explicit formulas for acovf of MA(1), MA(2) and ARMA(1,1)

* two names for lag polynomials ar = rhoy, ma = rhoe ?


Properties:
Judge, ... (1985): The Theory and Practise of Econometrics

BigJudge p. 237ff:
If the time series process is a stationary ARMA(p,q), then
minimizing the sum of squares is asymptoticaly (as T-> inf)
equivalent to the exact Maximum Likelihood Estimator

Because Least Squares conditional on the initial information
does not use all information, in small samples exact MLE can
be better.

Without the normality assumption, the least squares estimator
is still consistent under suitable conditions, however not
efficient

Author: josefpktd
License: BSD
'''

import numpy as np
from scipy import signal, optimize, linalg
from gwstatsmodels.base.model import LikelihoodModel

#this has been copied to new arma_mle.py - keep temporarily for easier lookup
class ARIMA(LikelihoodModel):
    '''currently ARMA only, no differencing used - no I

    parameterized as
         rhoy(L) y_t = rhoe(L) eta_t

    A instance of this class preserves state, so new class instances should
    be created for different examples
    '''
    def __init__(self, endog, exog=None):
        super(ARIMA, self).__init__(endog, exog)
        if endog.ndim == 1:
            endog = endog[:,None]
        elif endog.ndim > 1 and endog.shape[1] != 1:
            raise ValueError("Only the univariate case is implemented")
        self.endog = endog # overwrite endog
        if exog is not None:
            raise ValueError("Exogenous variables are not yet supported.")

    def fit(self, order=(0,0,0), method="ls", rhoy0=None, rhoe0=None):
        '''
        Estimate lag coefficients of an ARIMA process.

        Parameters
        ----------
            order : sequence
                p,d,q where p is the number of AR lags, d is the number of
                differences to induce stationarity, and q is the number of
                MA lags to estimate.
            method : str {"ls", "ssm"}
                Method of estimation.  LS is conditional least squares.
                SSM is state-space model and the Kalman filter is used to
                maximize the exact likelihood.
            rhoy0, rhoe0 : array_like (optional)
                starting values for estimation

        Returns
        -------
            rh, cov_x, infodict, mesg, ier : output of scipy.optimize.leastsq
            rh :
                estimate of lag parameters, concatenated [rhoy, rhoe]
            cov_x :
                unscaled (!) covariance matrix of coefficient estimates
        '''
        if not hasattr(order, '__iter__'):
            raise ValueError("order must be an iterable sequence.  Got type \
%s instead" % type(order))

        p,d,q = order

        if d > 0:
            raise ValueError("Differencing not implemented yet")
            # assume no constant, ie mu = 0
            # unless overwritten then use w_bar for mu
            Y = np.diff(endog, d, axis=0) #TODO: handle lags?

        x = self.endog.squeeze() # remove the squeeze might be needed later
        def errfn( rho):
            #rhoy, rhoe = rho
            rhoy = np.concatenate(([1], rho[:p]))
            rhoe = np.concatenate(([1], rho[p:]))
            etahatr = signal.lfilter(rhoy, rhoe, x)
            #print rho,np.sum(etahatr*etahatr)
            return etahatr

        if rhoy0 is None:
            rhoy0 = 0.5 * np.ones(p)
        if rhoe0 is None:
            rhoe0 = 0.5 * np.ones(q)

        method = method.lower()

        if method == "ls":
            rh, cov_x, infodict, mesg, ier = \
               optimize.leastsq(errfn, np.r_[rhoy0, rhoe0],ftol=1e-10,full_output=True)
#TODO: integrate this into the MLE.fit framework?
        elif method == "ssm":
            pass
        else:
            # fmin_bfgs is slow or doesn't work yet
            errfnsum = lambda rho : np.sum(errfn(rho)**2)
            #xopt, {fopt, gopt, Hopt, func_calls, grad_calls
            rh,fopt, gopt, cov_x, _,_, ier = \
                optimize.fmin_bfgs(errfnsum, np.r_[rhoy0, rhoe0], maxiter=2, full_output=True)
            infodict, mesg = None, None
        self.rh = rh
        self.rhoy = np.concatenate(([1], rh[:p]))
        self.rhoe = np.concatenate(([1], rh[p:])) #rh[-q:])) doesnt work for q=0
        self.error_estimate = errfn(rh)
        return rh, cov_x, infodict, mesg, ier

    def errfn(self, rho=None, p=None, x=None):
        ''' duplicate -> remove one
        '''
        #rhoy, rhoe = rho
        if not rho is None:
            rhoy = np.concatenate(([1],  rho[:p]))
            rhoe = np.concatenate(([1],  rho[p:]))
        else:
            rhoy = self.rhoy
            rhoe = self.rhoe
        etahatr = signal.lfilter(rhoy, rhoe, x)
        #print rho,np.sum(etahatr*etahatr)
        return etahatr

    def predicted(self, rhoy=None, rhoe=None):
        '''past predicted values of time series
        just added, not checked yet
        '''
        if rhoy is None:
            rhoy = self.rhoy
        if rhoe is None:
            rhoe = self.rhoe
        return self.x + self.error_estimate

    def forecast(self, ar=None, ma=None, nperiod=10):
        eta = np.r_[self.error_estimate, np.zeros(nperiod)]
        if ar is None:
            ar = self.rhoy
        if ma is None:
            ma = self.rhoe
        return signal.lfilter(ma, ar, eta)

#TODO: is this needed as a method at all?
    @classmethod
    def generate_sample(cls, ar, ma, nsample, std=1):
        eta = std * np.random.randn(nsample)
        return signal.lfilter(ma, ar, eta)



def arma_generate_sample(ar, ma, nsample, sigma=1, distrvs=np.random.randn, burnin=0):
    '''generate an random sample of an ARMA process

    Parameters
    ----------
    ar : array_like, 1d
        coefficient for autoregressive lag polynomial, including zero lag
    ma : array_like, 1d
        coefficient for moving-average lag polynomial, including zero lag
    nsample : int
        length of simulated time series
    sigma : float
        standard deviation of noise
    distrvs : function, random number generator
        function that generates the random numbers, and takes sample size
        as argument
        default: np.random.randn
        TODO: change to size argument
    burnin : integer (default: 0)
        to reduce the effect of initial conditions, burnin observations at the
        beginning of the sample are dropped


    Returns
    -------
    acovf : array
        autocovariance of ARMA process given by ar, ma


    '''
    #TODO: unify with ArmaProcess method
    eta = sigma * distrvs(nsample+burnin)
    return signal.lfilter(ma, ar, eta)[burnin:]

def arma_acovf(ar, ma, nobs=10):
    '''theoretical autocovariance function of ARMA process

    Parameters
    ----------
    ar : array_like, 1d
        coefficient for autoregressive lag polynomial, including zero lag
    ma : array_like, 1d
        coefficient for moving-average lag polynomial, including zero lag

    Returns
    -------
    acovf : array
        autocovariance of ARMA process given by ar, ma

    See Also
    --------
    arma_acf
    acovf


    Notes
    -----
    Tries to do some crude numerical speed improvements for cases
    with high persistance. However, this algorithm is slow if the process is
    highly persistent and only a few autocovariances are desired.
    '''
    #increase length of impulse response for AR closer to 1
    #maybe cheap/fast enough to always keep nobs for ir large
    if np.abs(np.sum(ar)-1) > 0.9:
        nobs_ir = max(1000, 2* nobs)   #no idea right now how large it is needed
    else:
        nobs_ir = max(100, 2* nobs)   #no idea right now
    ir = arma_impulse_response(ar, ma, nobs=nobs_ir)
    #better save than sorry (?), I have no idea about the required precision
    #only checked for AR(1)
    while ir[-1] > 5*1e-5:
        nobs_ir *= 10
        ir = arma_impulse_response(ar, ma, nobs=nobs_ir)
    #again no idea where the speed break points are:
    if nobs_ir > 50000 and nobs < 1001:
        acovf = np.array([np.dot(ir[:nobs-t], ir[t:nobs]) for t in range(nobs)])
    else:
        acovf = np.correlate(ir,ir,'full')[len(ir)-1:]
    return acovf[:nobs]

def arma_acf(ar, ma, nobs=10):
    '''theoretical autocovariance function of ARMA process

    Parameters
    ----------
    ar : array_like, 1d
        coefficient for autoregressive lag polynomial, including zero lag
    ma : array_like, 1d
        coefficient for moving-average lag polynomial, including zero lag

    Returns
    -------
    acovf : array
        autocovariance of ARMA process given by ar, ma


    See Also
    --------
    arma_acovf
    acf
    acovf

    '''
    acovf = arma_acovf(ar, ma, nobs)
    return acovf/acovf[0]

def arma_pacf(ar, ma, nobs=10):
    '''partial autocorrelation function of an ARMA process

    Notes
    -----
    solves yule-walker equation for each lag order up to nobs lags

    not tested/checked yet
    '''
    apacf = np.zeros(nobs)
    acov = arma_acf(ar,ma, nobs=nobs+1)

    apacf[0] = 1.
    for k in range(2,nobs+1):
        r = acov[:k];
        apacf[k-1] = linalg.solve(linalg.toeplitz(r[:-1]), r[1:])[-1]
    return apacf

def arma_periodogram(ar, ma, worN=None, whole=0):
    '''periodogram for ARMA process given by lag-polynomials ar and ma

    Parameters
    ----------
    ar : array_like
        autoregressive lag-polynomial with leading 1 and lhs sign
    ma : array_like
        moving average lag-polynomial with leading 1
    worN : {None, int}, optional
        option for scipy.signal.freqz   (read "w or N")
        If None, then compute at 512 frequencies around the unit circle.
        If a single integer, the compute at that many frequencies.
        Otherwise, compute the response at frequencies given in worN
    whole : {0,1}, optional
        options for scipy.signal.freqz
        Normally, frequencies are computed from 0 to pi (upper-half of
        unit-circle.  If whole is non-zero compute frequencies from 0 to 2*pi.

    Returns
    -------
    w : array
        frequencies
    sd : array
        periodogram, spectral density

    Notes
    -----
    Normalization ?

    This uses signal.freqz, which does not use fft. There is a fft version
    somewhere.

    '''
    w, h = signal.freqz(ma, ar, worN=worN, whole=whole)
    sd = np.abs(h)**2/np.sqrt(2*np.pi)
    if np.sum(np.isnan(h)) > 0:
        # this happens with unit root or seasonal unit root'
        print 'Warning: nan in frequency response h, maybe a unit root'
    return w, sd


def arma_impulse_response(ar, ma, nobs=100):
    '''get the impulse response function (MA representation) for ARMA process

    Parameters
    ----------
    ma : array_like, 1d
        moving average lag polynomial
    ar : array_like, 1d
        auto regressive lag polynomial
    nobs : int
        number of observations to calculate

    Returns
    -------
    ir : array, 1d
        impulse response function with nobs elements

    Notes
    -----
    This is the same as finding the MA representation of an ARMA(p,q).
    By reversing the role of ar and ma in the function arguments, the
    returned result is the AR representation of an ARMA(p,q), i.e

    ma_representation = arma_impulse_response(ar, ma, nobs=100)
    ar_representation = arma_impulse_response(ma, ar, nobs=100)

    fully tested against matlab

    Examples
    --------
    AR(1)

    >>> arma_impulse_response([1.0, -0.8], [1.], nobs=10)
    array([ 1.        ,  0.8       ,  0.64      ,  0.512     ,  0.4096    ,
            0.32768   ,  0.262144  ,  0.2097152 ,  0.16777216,  0.13421773])

    this is the same as

    >>> 0.8**np.arange(10)
    array([ 1.        ,  0.8       ,  0.64      ,  0.512     ,  0.4096    ,
            0.32768   ,  0.262144  ,  0.2097152 ,  0.16777216,  0.13421773])

    MA(2)

    >>> arma_impulse_response([1.0], [1., 0.5, 0.2], nobs=10)
    array([ 1. ,  0.5,  0.2,  0. ,  0. ,  0. ,  0. ,  0. ,  0. ,  0. ])

    ARMA(1,2)

    >>> arma_impulse_response([1.0, -0.8], [1., 0.5, 0.2], nobs=10)
    array([ 1.        ,  1.3       ,  1.24      ,  0.992     ,  0.7936    ,
            0.63488   ,  0.507904  ,  0.4063232 ,  0.32505856,  0.26004685])
    '''
    impulse = np.zeros(nobs)
    impulse[0] = 1.
    return signal.lfilter(ma, ar, impulse)

#alias, easier to remember
arma2ma = arma_impulse_response

#alias, easier to remember
def arma2ar(ar, ma, nobs=100):
    '''get the AR representation of an ARMA process

    Parameters
    ----------
    ar : array_like, 1d
        auto regressive lag polynomial
    ma : array_like, 1d
        moving average lag polynomial
    nobs : int
        number of observations to calculate

    Returns
    -------
    ar : array, 1d
        coefficients of AR lag polynomial with nobs elements
    `

    Notes
    -----
    This is just an alias for

    ``ar_representation = arma_impulse_response(ma, ar, nobs=100)``

    fully tested against matlab

    Examples
    --------

    '''
    return arma_impulse_response(ma, ar, nobs=nobs)


#moved from sandbox.tsa.try_fi
def ar2arma(ar_des, p, q, n=20, mse='ar', start=None):
    '''find arma approximation to ar process

    This finds the ARMA(p,q) coefficients that minimize the integrated
    squared difference between the impulse_response functions
    (MA representation) of the AR and the ARMA process. This does
    currently not check whether the MA lagpolynomial of the ARMA
    process is invertible, neither does it check the roots of the AR
    lagpolynomial.

    Parameters
    ----------
    ar_des : array_like
        coefficients of original AR lag polynomial, including lag zero
    p, q : int
        length of desired ARMA lag polynomials
    n : int
        number of terms of the impuls_response function to include in the
        objective function for the approximation
    mse : string, 'ar'
        not used yet,

    Returns
    -------
    ar_app, ma_app : arrays
        coefficients of the AR and MA lag polynomials of the approximation
    res : tuple
        result of optimize.leastsq

    Notes
    -----
    Extension is possible if we want to match autocovariance instead
    of impulse response function.

    TODO: convert MA lag polynomial, ma_app, to be invertible, by mirroring
    roots outside the unit intervall to ones that are inside. How do we do
    this?

    '''
    #p,q = pq
    def msear_err(arma, ar_des):
        ar, ma = np.r_[1, arma[:p-1]], np.r_[1, arma[p-1:]]
        ar_approx = arma_impulse_response(ma, ar,  n)
##        print ar,ma
##        print ar_des.shape, ar_approx.shape
##        print ar_des
##        print ar_approx
        return (ar_des - ar_approx) #((ar - ar_approx)**2).sum()
    if start is None:
        arma0 = np.r_[-0.9* np.ones(p-1), np.zeros(q-1)]
    else:
        arma0 = start
    res = optimize.leastsq(msear_err, arma0, ar_des, maxfev=5000)#, full_output=True)
    #print res
    arma_app = np.atleast_1d(res[0])
    ar_app = np.r_[1, arma_app[:p-1]],
    ma_app = np.r_[1, arma_app[p-1:]]
    return ar_app, ma_app, res



def lpol2index(ar):
    '''remove zeros from lagpolynomial, squeezed representation with index

    Parameters
    ----------
    ar : array_like
        coefficients of lag polynomial

    Returns
    -------
    coeffs : array
        non-zero coefficients of lag polynomial
    index : array
        index (lags) of lagpolynomial with non-zero elements
    '''
    ar = np.asarray(ar)
    index = np.nonzero(ar)[0]
    coeffs = ar[index]
    return coeffs, index

def index2lpol(coeffs, index):
    '''expand coefficients to lag poly

    Parameters
    ----------
    coeffs : array
        non-zero coefficients of lag polynomial
    index : array
        index (lags) of lagpolynomial with non-zero elements
    ar : array_like
        coefficients of lag polynomial

    Returns
    -------
    ar : array_like
        coefficients of lag polynomial

    '''
    n = max(index)
    ar = np.zeros(n)
    ar[index] = coeffs
    return ar

#moved from sandbox.tsa.try_fi
def lpol_fima(d, n=20):
    '''MA representation of fractional integration

    .. math:: (1-L)^{-d} for |d|<0.5  or |d|<1 (?)

    Parameters
    ----------
    d : float
        fractional power
    n : int
        number of terms to calculate, including lag zero

    Returns
    -------
    ma : array
        coefficients of lag polynomial

    '''
    #hide import inside function until we use this heavily
    from scipy.special import gamma, gammaln
    j = np.arange(n)
    return np.exp(gammaln(d+j) - gammaln(j+1) - gammaln(d))

#moved from sandbox.tsa.try_fi
def lpol_fiar(d, n=20):
    '''AR representation of fractional integration

    .. math:: (1-L)^{d} for |d|<0.5  or |d|<1 (?)

    Parameters
    ----------
    d : float
        fractional power
    n : int
        number of terms to calculate, including lag zero

    Returns
    -------
    ar : array
        coefficients of lag polynomial

    Notes:
    first coefficient is 1, negative signs except for first term,
    ar(L)*x_t
    '''
    #hide import inside function until we use this heavily
    from scipy.special import gamma, gammaln
    j = np.arange(n)
    ar = - np.exp(gammaln(-d+j) - gammaln(j+1) - gammaln(-d))
    ar[0] = 1
    return ar

#moved from sandbox.tsa.try_fi
def lpol_sdiff(s):
    '''return coefficients for seasonal difference (1-L^s)

    just a trivial convenience function

    Parameters
    ----------
    s : int
        number of periods in season

    Returns
    -------
    sdiff : list, length s+1

    '''
    return [1] + [0]*(s-1) + [-1]



def deconvolve(num, den, n=None):
    """Deconvolves divisor out of signal, division of polynomials for n terms

    calculates den^{-1} * num

    Parameters
    ----------
    num : array_like
        signal or lag polynomial
    denom : array_like
        coefficients of lag polynomial (linear filter)
    n : None or int
        number of terms of quotient

    Returns
    -------
    quot : array
        quotient or filtered series
    rem : array
        remainder

    Notes
    -----
    If num is a time series, then this applies the linear filter den^{-1}.
    If both num and den are both lagpolynomials, then this calculates the
    quotient polynomial for n terms and also returns the remainder.

    This is copied from scipy.signal.signaltools and added n as optional
    parameter.

    """
    num = np.atleast_1d(num)
    den = np.atleast_1d(den)
    N = len(num)
    D = len(den)
    if D > N and n is None:
        quot = [];
        rem = num;
    else:
        if n is None:
            n = N-D+1
        input = np.zeros(n, float)
        input[0] = 1
        quot = signal.lfilter(num, den, input)
        num_approx = signal.convolve(den, quot, mode='full')
        if len(num) < len(num_approx):  # 1d only ?
            num = np.concatenate((num, np.zeros(len(num_approx)-len(num))))
        rem = num - num_approx
    return quot, rem


class ArmaProcess(object):
    '''represents an ARMA process for given lag-polynomials

    This is a class to bring together properties of the process.
    It does not do any estimation or statistical analysis.

    maybe needs special handling for unit roots

    '''
    def __init__(self, ar, ma, nobs=None):
        self.ar = np.asarray(ar)
        self.ma = np.asarray(ma)
        self.arcoefs = -self.ar[1:]
        self.macoefs = self.ma[1:]
        self.arpoly = np.polynomial.Polynomial(self.ar)
        self.mapoly = np.polynomial.Polynomial(self.ma)
        self.nobs = nobs

    @classmethod
    def from_coeffs(cls, arcoefs, macoefs, nobs=None):
        '''create ArmaProcess instance from coefficients of the lag-polynomials
        '''
        return cls(np.r_[1, -arcoefs], np.r_[1, macoefs], nobs=nobs)

    @classmethod
    def from_estimation(cls, model_results, nobs=None):
        '''create ArmaProcess instance from estimation results
        '''
        arcoefs = model_results.params[:model_results.nar]
        macoefs = model_results.params[model_results.nar:
                                       model_results.nar+model_results.nma]
        return cls(np.r_[1, -arcoefs], np.r_[1, macoefs], nobs=nobs)

    def __mul__(self, oth):
        if isinstance(oth, self.__class__):
            ar = (self.arpoly * oth.arpoly).coef
            ma = (self.mapoly * oth.mapoly).coef
        else:
            try:
                aroth, maoth = oth
                arpolyoth = np.polynomial.Polynomial(aroth)
                mapolyoth = np.polynomial.Polynomial(maoth)
                ar = (self.arpoly * arpolyoth).coef
                ma = (self.mapoly * mapolyoth).coef
            except:
                print('other is not a valid type')
                raise
        return self.__class__(ar, ma, nobs=self.nobs)

    def __repr__(self):
        return 'ArmaProcess(%r, %r, nobs=%d)' % (self.ar.tolist(), self.ma.tolist(),
                                            self.nobs)
    def __str__(self):
        return 'ArmaProcess\nAR: %r\nMA: %r' % (self.ar.tolist(), self.ma.tolist())


    def acovf(self, nobs=None):
         nobs = nobs or self.nobs
         return arma_acovf(self.ar, self.ma, nobs=nobs)

    acovf.__doc__ = arma_acovf.__doc__

    def acf(self, nobs=None):
         nobs = nobs or self.nobs
         return arma_acf(self.ar, self.ma, nobs=nobs)

    acf.__doc__ = arma_acf.__doc__

    def pacf(self, nobs=None):
         nobs = nobs or self.nobs
         return arma_pacf(self.ar, self.ma, nobs=nobs)

    pacf.__doc__ = arma_pacf.__doc__

    def periodogram(self, nobs=None):
         nobs = nobs or self.nobs
         return arma_periodogram(self.ar, self.ma, worN=nobs)

    periodogram.__doc__ = arma_periodogram.__doc__

    def impulse_response(self, nobs=None):
         nobs = nobs or self.nobs
         return arma_impulse_response(self.ar, self.ma, worN=nobs)

    impulse_response.__doc__ = arma_impulse_response.__doc__

    def arma2ma(self, nobs=None):
         nobs = nobs or self.nobs
         return arma2ma(self.ar, self.ma, nobs=nobs)

    arma2ma.__doc__ = arma2ma.__doc__

    def arma2ar(self, nobs=None):
         nobs = nobs or self.nobs
         return arma2ar(self.ar, self.ma, nobs=nobs)

    arma2ar.__doc__ = arma2ar.__doc__

    def ar_roots(self):
        '''roots of autoregressive lag-polynomial
        '''
        return self.arpoly.roots()

    def ma_roots(self):
        '''roots of moving average lag-polynomial
        '''
        return self.mapoly.roots()

    def isstationary(self):
        '''Arma process is stationary if AR roots are outside unit circle

        Returns
        -------
        isstationary : boolean
             True if autoregressive roots are outside unit circle

        '''
        if np.all(np.abs(self.ar_roots()) > 1):
            return True
        else:
            return False

    def isinvertible(self):
        '''Arma process is invertible if MA roots are outside unit circle

        Returns
        -------
        isinvertible : boolean
             True if moving average roots are outside unit circle

        '''
        if np.all(np.abs(self.ma_roots()) > 1):
            return True
        else:
            return False

    def invertroots(self, retnew=False):
        '''make MA polynomial invertible by inverting roots inside unit circle

        Parameters
        ----------
        retnew : boolean
            If False (default), then return the lag-polynomial as array.
            If True, then return a new instance with invertible MA-polynomial

        Returns
        -------
        manew : array
           new invertible MA lag-polynomial, returned if retnew is false.
        wasinvertible : boolean
           True if the MA lag-polynomial was already invertible, returned if
           retnew is false.

        armaprocess : new instance of class
           If retnew is true, then return a new instance with invertible
           MA-polynomial


        '''
        pr = self.ma_roots()
        insideroots = np.abs(pr)<1
        if insideroots.any():
            pr[np.abs(pr)<1] = 1./pr[np.abs(pr)<1]
            pnew = poly.Polynomial.fromroots(pr)
            mainv = pn.coef/pnew.coef[0]
            wasinvertible = False
        else:
            mainv = self.ma
            wasinvertible = True
        if retnew:
            return self.__class__(self.ar, mainv, nobs=self.nobs)
        else:
            return mainv, wasinvertible

    def generate_sample(self, size=100, scale=1, distrvs=None, axis=0, burnin=0):
        '''generate ARMA samples

        Parameters
        ----------
        size : int or tuple of ints
            If size is an integer, then this creates a 1d timeseries of length size.
            If size is a tuple, then the timeseries is along axis. All other axis
            have independent arma samples.

        Returns
        -------
        rvs : ndarray
            random sample(s) of arma process

        Notes
        -----
        Should work for n-dimensional with time series along axis, but not tested
        yet. Processes are sampled independently.

        '''
        if distrvs is None:
            distrvs = np.random.normal
        if np.ndim(size) == 0:
                size = [size]
        if burnin:
            #handle burin time for nd arrays
            #maybe there is a better trick in scipy.fft code
            newsize = list(size)
            newsize[axis] += burnin
            newsize = tuple(newsize)
            fslice = [slice(None)]*len(newsize)
            fslice[axis] = slice(burnin, None, None)
            fslice = tuple(fslice)
        else:
            newsize = tuple(size)
            fslice = tuple([slice(None)]*np.ndim(newsize))

        eta = scale * distrvs(size=newsize)
        return signal.lfilter(self.ma, self.ar, eta, axis=axis)[fslice]







__all__ = ['arma_acf', 'arma_acovf', 'arma_generate_sample',
           'arma_impulse_response', 'arma2ar', 'arma2ma', 'deconvolve',
           'lpol2index', 'index2lpol']


if __name__ == '__main__':


    # Simulate AR(1)
    #--------------
    # ar * y = ma * eta
    ar = [1, -0.8]
    ma = [1.0]

    # generate AR data
    eta = 0.1 * np.random.randn(1000)
    yar1 = signal.lfilter(ar, ma, eta)

    print "\nExample 0"
    arest = ARIMA(yar1)
    rhohat, cov_x, infodict, mesg, ier = arest.fit((1,0,1))
    print rhohat
    print cov_x

    print "\nExample 1"
    ar = [1.0,  -0.8]
    ma = [1.0,  0.5]
    y1 = arest.generate_sample(ar,ma,1000,0.1)
    arest = ARIMA(y1)
    rhohat1, cov_x1, infodict, mesg, ier = arest.fit((1,0,1))
    print rhohat1
    print cov_x1
    err1 = arest.errfn(x=y1)
    print np.var(err1)
    import gwstatsmodels.api as sm
    print sm.regression.yule_walker(y1, order=2, inv=True)

    print "\nExample 2"
    nsample = 1000
    ar = [1.0, -0.6, -0.1]
    ma = [1.0,  0.3,  0.2]
    y2 = ARIMA.generate_sample(ar,ma,nsample,0.1)
    arest2 = ARIMA(y2)
    rhohat2, cov_x2, infodict, mesg, ier = arest2.fit((1,0,2))
    print rhohat2
    print cov_x2
    err2 = arest.errfn(x=y2)
    print np.var(err2)
    print arest2.rhoy
    print arest2.rhoe
    print "true"
    print ar
    print ma
    rhohat2a, cov_x2a, infodict, mesg, ier = arest2.fit((2,0,2))
    print rhohat2a
    print cov_x2a
    err2a = arest.errfn(x=y2)
    print np.var(err2a)
    print arest2.rhoy
    print arest2.rhoe
    print "true"
    print ar
    print ma

    print sm.regression.yule_walker(y2, order=2, inv=True)

    print "\nExample 20"
    nsample = 1000
    ar = [1.0]#, -0.8, -0.4]
    ma = [1.0,  0.5,  0.2]
    y3 = ARIMA.generate_sample(ar,ma,nsample,0.01)
    arest20 = ARIMA(y3)
    rhohat3, cov_x3, infodict, mesg, ier = arest20.fit((2,0,0))
    print rhohat3
    print cov_x3
    err3 = arest20.errfn(x=y3)
    print np.var(err3)
    print np.sqrt(np.dot(err3,err3)/nsample)
    print arest20.rhoy
    print arest20.rhoe
    print "true"
    print ar
    print ma

    rhohat3a, cov_x3a, infodict, mesg, ier = arest20.fit((0,0,2))
    print rhohat3a
    print cov_x3a
    err3a = arest20.errfn(x=y3)
    print np.var(err3a)
    print np.sqrt(np.dot(err3a,err3a)/nsample)
    print arest20.rhoy
    print arest20.rhoe
    print "true"
    print ar
    print ma

    print sm.regression.yule_walker(y3, order=2, inv=True)

    print "\nExample 02"
    nsample = 1000
    ar = [1.0, -0.8, 0.4] #-0.8, -0.4]
    ma = [1.0]#,  0.8,  0.4]
    y4 = ARIMA.generate_sample(ar,ma,nsample)
    arest02 = ARIMA(y4)
    rhohat4, cov_x4, infodict, mesg, ier = arest02.fit((2,0,0))
    print rhohat4
    print cov_x4
    err4 = arest02.errfn(x=y4)
    print np.var(err4)
    sige = np.sqrt(np.dot(err4,err4)/nsample)
    print sige
    print sige * np.sqrt(np.diag(cov_x4))
    print np.sqrt(np.diag(cov_x4))
    print arest02.rhoy
    print arest02.rhoe
    print "true"
    print ar
    print ma

    rhohat4a, cov_x4a, infodict, mesg, ier = arest02.fit((0,0,2))
    print rhohat4a
    print cov_x4a
    err4a = arest02.errfn(x=y4)
    print np.var(err4a)
    sige = np.sqrt(np.dot(err4a,err4a)/nsample)
    print sige
    print sige * np.sqrt(np.diag(cov_x4a))
    print np.sqrt(np.diag(cov_x4a))
    print arest02.rhoy
    print arest02.rhoe
    print "true"
    print ar
    print ma
    import gwstatsmodels.api as sm
    print sm.regression.yule_walker(y4, order=2, method='mle', inv=True)


    import matplotlib.pyplot as plt
    plt.plot(arest2.forecast()[-100:])
    #plt.show()

    ar1, ar2 = ([1, -0.4], [1, 0.5])
    ar2 = [1, -1]
    lagpolyproduct = np.convolve(ar1, ar2)
    print deconvolve(lagpolyproduct, ar2, n=None)
    print signal.deconvolve(lagpolyproduct, ar2)
    print deconvolve(lagpolyproduct, ar2, n=10)

